鹵鹽載體無機鹽阻化煤自燃的機理及性能

張嬿妮; 侯云超; 劉博; 鄧軍; 劉春輝; 楊晶晶; 溫心宇

doi:10.13374/j.issn2095-9389.2020.12.25.001

鹵鹽載體無機鹽阻化煤自燃的機理及性能

doi: 10.13374/j.issn2095-9389.2020.12.25.001

張嬿妮^{1, 2, 3, ,},
侯云超^{1, 3},
劉博^{1, 3},
鄧軍^{1, 3},
劉春輝^{1, 3},
楊晶晶^{1, 3},
溫心宇^{1, 3}

1.
西安科技大學安全科學與工程學院, 西安 710054
2.
國土資源部煤炭資源勘查與綜合利用重點實驗室, 西安 710054
3.
西安科技大學陜西省煤火災害防治重點實驗室, 西安 710054

基金項目: 國家重點研發計劃資助項目（2018YFC0807900）; 國家自然科學基金資助項目（51674191）

詳細信息

通訊作者:
E-mail: zyn2099@xust.edu.cn

中圖分類號: TD752.2
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- 文章訪問數: 589
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- 被引次數: 0
出版歷程
- 收稿日期: 2020-12-25
- 網絡出版日期: 2021-01-29
- 刊出日期: 2021-10-12

Mechanism and performance of coal spontaneous combustion with a halide carrier inorganic salt inhibitor

ZHANG Yan-ni^{1, 2, 3
, ,},
HOU Yun-chao^{1, 3},
LIU Bo^{1, 3},
DENG Jun^{1, 3},
LIU Chun-hui^{1, 3},
YANG Jing-jing^{1, 3},
WEN Xin-yu^{1, 3}

1.
College of Safety Science and Engineering, Xi’an University of Science and Technology, Xi’an 710054, China
2.
Key Laboratory of Coal Resources Exploration and Comprehensive Utilization, Ministry of Land and Resources, Xi’an 710021, China
3.
Shanxi Key Laboratory of Prevention and Control of Coal Fire, Xi’an University of Science and Technology, Xi’an 710054, China

More Information

Corresponding author: E-mail: zyn2099@xust.edu.cn

摘要

摘要: 為了研究鹵鹽載體無機鹽阻化劑對煤自燃的阻化機理及性能，采用差示掃描量熱儀（DSC）測試了在稀土水滑石、MgCl₂和鹵鹽載體無機鹽三種不同阻化劑作用下，煤自燃過程中分階段特征、特征溫度、熱效應和表觀活化能等參數變化規律。測試結果表明，稀土水滑石層板的?OH能夠與煤分子中的?COOH等酸性官能團產生弱氫鍵，造成?COOH等酸性官能團的活性減弱；Mg²⁺與煤分子中的—COO?發生絡合作用，生成了?COOMg?，造成?COO?內的 C=O活性減弱是鹵鹽載體無機鹽抑制煤自燃的主要機理。煤樣中添加鹵鹽載體無機鹽后DSC曲線吸熱峰均出現雙峰或多峰，且較原煤的峰值溫度后移了50～60 ℃、T₁溫度后移了90～100 ℃、總放熱量降低了19～27 kJ?g^?1，而且有效的提高了煤體各階段的表觀活化能。研究表明鹵鹽載體無機鹽阻化劑可有效抑制煤自燃反應進程。
- 鹵鹽載體無機鹽 /
- 阻化劑 /
- 煤自燃 /
- DSC /
- 表觀活化能
Abstract: Coal spontaneous combustion seriously restricts the safe production of coal mines, and adding an inhibitor is one of the effective methods to prevent coal spontaneous combustion. To improve the pertinence and high efficiency of the inhibitor, this paper considered the intrinsic properties and external conditions that affect the occurrence of coal spontaneous combustion, combined with the characteristics that the rare earth hydrotalcite can effectively improve the thermal stability, coupling, and flame retardancy of the coal and the halide inhibitor. The halide inhibitor can enhance the permeability, dispersion, and uniformity of the rare earth hydrotalcite as a carrier. The halide carrier inorganic salt inhibitor was prepared. To study the inhibition mechanism and performance of the halide carrier inorganic salt inhibitor on coal spontaneous combustion, differential scanning calorimetry (DSC) was used to test the variation law of parameters, such as stage characteristics, characteristic temperature, thermal effect, and apparent activation energy in the process of coal spontaneous combustion under the action of a rare earth hydrotalcite, MgCl₂ and a halide carrier inorganic salt inhibitor. Test results reveal that the OH of the rare earth hydrotalcite laminate can generate a weak hydrogen bond with acidic functional groups such as ?COOH in coal molecules so that the activity of the acidic functional groups is weakened. Mg²⁺ complexes with ?COO? in coal molecules to form ?COOMg?, resulting in the weakening of the C=O activity in ?COO?, which is the main mechanism of the halide carrier inorganic salts inhibiting coal spontaneous combustion. The endothermic peak of the DSC curve appears as a double peak or multi-peak after the addition of halide carrier inorganic salts to the coal sample. Compared with the raw coal, the peak temperature is shifted back by 50–60 ℃, the T₁ temperature is shifted back by 90–100 ℃, and the total heat release decreased by 19–27 kJ?g^?1. Furthermore, the apparent activation energy of each stage of the coal body is effectively improved. Results revealed that the halide carrier inorganic salt inhibitor could effectively inhibit the reaction process of coal spontaneous combustion.
- halide carrier inorganic salt /
- inhibitor /
- coal spontaneous combustion /
- differential scanning calorimetry /
- apparent activation energy

HTML全文

圖 1 試驗樣品掃描電鏡照片。（a）試驗樣品1；（b）試驗樣品2；（c）試驗樣品7；（d）試驗樣品8

Figure 1. Test sample SEM: (a) sample 1; (b) sample 2; (c) sample 7; (d) sample 8

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圖 2 試驗樣品EDS圖。（a）試驗樣品1；（b）試驗樣品2；（c）試驗樣品7；（d）試驗樣品8

Figure 2. Test sample EDS: (a) sample 1; (b) sample 2; (c) sample 7; (d) sample 8

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圖 3 試驗樣品熱釋放速率曲線圖。（a）試驗樣品1～6；（b）試驗樣品7～12

Figure 3. Curve of the heat release rate of the test sample: (a) sample 1–6; (b) sample 7–12

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圖 4 各樣品熱釋放速率曲線圖。（a）試驗樣品1；（b）試驗樣品2；（c）試驗樣品3；（d）試驗樣品4；（e）試驗樣品5；（f）試驗樣品6；（g）試驗樣品7；（h）試驗樣品8；（i）試驗樣品9；（j）試驗樣品10；（k）試驗樣品11；（l）試驗樣品12

Figure 4. Heat release rate curve: (a) sample 1；(b) sample 2；(c) sample 3；(d) sample 4; (e) sample 5；(f) sample 6；(g) sample 7；(h) sample 8; (i) sample 9；(j) sample 10；(k) sample 11；(l) sample 12

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圖 5 試驗樣品緩慢放熱階段表觀活化能曲線。（a）試驗樣品1；（b）試驗樣品7

Figure 5. Apparent activation energy curve of the test sample during the slow heat release stage: (a) sample 1; (b) sample 7

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圖 6 試驗樣品快速放熱階段表觀活化能曲線。（a）試驗樣品1；（b）試驗樣品7

Figure 6. Apparent activation energy curve of the test sample during the rapid heat release stage: (a) sample 1; (b) sample 7

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表 1 煤的工業分析與元素分析（質量分數）

Table 1. Industrial analysis and element analysis of coal %

Proximate analysis				Ultimate analysis
M_ad	A_ad	V_ad	F_Cad	C_daf	H_daf	N_da	O_da	S_daf
4.66	15.84	32.88	46.62	76.04	3.95	0.68	19.25	0.08

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表 2 阻化劑配制成分表（質量分數）

Table 2. Composition list of the inhibitor %

Sample	Rare earth hydrotalcite	H₂O	Sample	MgCl₂	Rare earth hydrotalcite	H₂O
1	0	100	7	20	0	80
2	1	99	8	20	1	79
3	3	97	9	20	3	77
4	5	95	10	20	5	75
5	7	93	11	20	7	73
6	9	91	12	20	9	71

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表 3 試驗樣品在不同氧化階段的放熱量

Table 3. Heat release of test samples at different oxidation stages

Sample	Total heat released/ (J?mg^?1)	Total heat absorbed (heat absorption stage)/ (J?mg^?1)	Slow heat release stage		Rapid heat release stage
Sample	Total heat released/ (J?mg^?1)	Total heat absorbed (heat absorption stage)/ (J?mg^?1)	Heat released/ (J?mg^?1)	Percentage of total heat released /%	Heat released/ (J?mg^?1)	Percentage of total heat released /%
1	74.31	1.72	29.49	39.69	44.82	60.31
2	88.76	1.6	30.02	33.82	58.74	66.18
3	98.6	0.12	25.46	25.82	73.14	74.17
4	94.48	0.13	21.68	22.94	72.8	77.05
5	103.83	0.31	27.37	26.36	76.46	73.64
6	98.13	0.48	33.53	34.17	64.6	65.83
7	63.09	1.17	19.22	30.46	43.87	69.53
8	49.17	1.06	15.63	31.79	33.54	68.21
9	53.31	1.08	16.18	30.35	37.13	69.65
10	55.37	1.6	17.73	32.02	37.64	67.98
11	47.11	1.77	16.06	34.09	31.05	65.91
12	48.68	2.31	16.18	33.24	32.5	66.76

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表 4 緩慢放熱階段表觀活化能參數

Table 4. Apparent activation energy parameters in the slow heat release stage

Sample	Fitting linear equation	Apparent activation energy, E / (J·mol^–1)	Correlation coefficient, R²
1	y=?3392.23468x+3.47896	28203.0391	0.97832
2	y=?4771.26045x+7.20905	39668.25938	0.95058
3	y=?3677.22585x+4.10123	30572.45572	0.96386
4	y=?3994.97463x+4.91556	33214.21907	0.97228
5	y=?4037.2746x+4.84162	33565.90102	0.9789
6	y=?4163.42638 x+5.24455	34614.72692	0.98845
7	y=?6428.62213x+9.04335	53447.56439	0.9187
8	y=?5443.14126x+7.62782	45254.27644	0.99003
9	y=?6140.78185x+9.03888	51054.4603	0.98428
10	y=?6653.1257x+ 9.91782	55314.08707	0.95261
11	y=?5802.11937x+8.25131	48238.82044	0.98814
12	y=?5623.12086 x+ 8.04004	46750.62683	0.9913

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表 5 快速放熱階段活化能參數

Table 5. Apparent activation energy parameters in the rapid heat release stage

Sample	Fitting linear equation	Apparent activation energy, E / (J·mol^–1)	Correlation coefficient, R²
1	y=?6881.26298x+7.89178	57210.82042	0.90249
2	y=?9425.37165x+11.82431	78362.5399	0.98207
3	y=?8808.86618x+10.8194	73236.91342	0.96555
4	y=?7816.14674x+9.33284	64983.444	0.9513
5	y=?7140.95942x+8.32359	59369.93645	0.93582
6	y=?7994.84827x+9.5651	66469.16852	0.94128
7	y=?9377.78707x+11.73499	77966.9217	0.97704
8	y=?10237.40606x+12.94076	85113.79398	0.95442
9	y=?8923.61423x+10.90617	74190.92871	0.94638
10	y=?10153.61359x+12.85178	84417.14339	0.9656
11	y=?10102.1723x+12.81694	83989.4605	0.9858
12	y=?10299.87431x+13.13003	85633.15501	0.96873

下載: 導出CSV

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